KR0176819B1 - Slider structure of a hermetic compressor - Google Patents

Abstract

The present invention relates to a hermetic electric compressor, conventionally coupled to the crank pin eccentric in the compression mechanism of the hermetic electric compressor, the crank so that the slider to move back, forth, left and right according to the circular motion of the crank pin to be geometrically centered inside the piston shell. Since the sliding coupled with the pin, due to the rotational moment of the slider according to the circular motion of the crank pin, the friction between the slider and the piston shell to increase the wear caused by this has caused a problem of lowering the reliability of the product, The present invention is to reduce the friction moment by forming the eccentric position of the coupling hole coupled with the geometric center of the slider and the crank pin in a circular motion to reduce the amount of friction to improve the life of the product and improve the reliability of the product will be.

Description

Slider structure of hermetic electric compressor

1 shows the structure of a general hermetic electric compressor,

(a) is a longitudinal cross-sectional view.

(b) is a perspective view of the compression mechanism.

(c) is a cross-sectional view of the pressure port portion.

2 is a view illustrating a coupling structure of a general piston shell and a slider.

(a) is a plan view.

(b) is a cross-sectional view.

3 shows a conventional slider structure.

(a) is a front view.

(b) is a side cross-sectional view.

4 shows a slider structure of the hermetic compressor according to the present invention.

(a) is a front view.

(b) is a side cross-sectional view.

5 is a graph showing the amount of abrasion according to the eccentric distance between the geometric center and the coupling hole of the slider to which the present invention is applied by experimental values.

6 is a front view illustrating the load and the frictional force acting on each part when the slider to which the present invention is applied moves.

* Explanation of symbols for main parts of the drawings

6: rotating shaft 7: piston

10: crank pin 11: piston shell

12,12 ': Slider 12a, 12'a: Joining hole

C: Eccentric Distance

The present invention relates to a slider structure of a hermetic electric compressor, and more particularly, to a frictional and abrasion generated in the process of converting the rotational movement of the rotary shaft into a reciprocating motion of the piston, thereby reducing the friction and abrasion, which can improve the life of the product and improve the performance. It relates to a slider structure of a compressor.

A general hermetic electric compressor is, as shown in FIG. 1, the upper and lower airtight containers (1, 2) and the upper and lower airtight containers (1, 2) to protect the compressor and prevent leakage of refrigerant. The through-hole is formed in the center and formed in the center of the frame (3) and the rotor (4) and the rotor (4) which is installed on the lower side of the frame (3) to rotate by external power source And a power mechanism part composed of a stator 5 paired with a rotor, and the rotor 4 is coupled to a center thereof, one side of which is eccentric, and an oil hole 6a is formed at the center thereof, thereby rotating by the rotor 4. A piston (7) coupled to an eccentric portion of the rotary shaft (6) and the rotary shaft (6) and reciprocated by rotation of the rotary shaft (6) and a cylinder (8) coupled to the piston (7) to compress refrigerant gas Compressor structure part etc. which are comprised are comprised.

The lower part of the lower airtight container 2 is filled with a lubricating oil for lubricating the inside of the compressor so that the lower part of the rotating shaft 6 is submerged.

In the hermetic electric compressor as described above, when the rotor 4 rotates by an external power source, the rotary shaft 6 coupled to the rotor 4 rotates, and the rotary shaft 6 rotates according to the rotation of the rotary shaft 6. Piston (7) coupled to the eccentric portion of the reciprocating motion inside the cylinder (8), compresses the low-temperature low-pressure refrigerant gas flowing into the cylinder (8) into a high-temperature high-pressure refrigerant gas to circulate into the refrigeration cycle Let's do it.

Referring to the structure and operation of the compression mechanism in the above process as follows. As shown in FIG. 2, the compression mechanism of the hermetic electric compressor has a rotary shaft 6 which is constricted in the center of the rotor 4 of the electric mechanism and rotates together with the rotor 4. It is installed, the disc-shaped counterbalance (9) is formed at the upper end of the rotary shaft (6), the crank pin (10) is installed eccentrically with the rotary shaft (6) on the counterbalance (9).

A cylinder 8 is installed in a direction perpendicular to the rotation shaft 6, and a piston 7 is inserted into the cylinder 8, and a central portion penetrates through an end portion of the piston 7 in a longitudinal direction on an outer circumferential surface thereof. The piston 12 with the long hole 11a formed therein is coupled, and as shown in FIG. 3 at the center of the piston shell 11, the slider 12 having the engagement hole 12a formed in the center of the round bar shape. ) Is inserted, and the crank pin 10 is inserted into the coupling hole 12a of the slider 12 inserted into the piston shell 11.

Compressor structure configured as described above is a crank pin (10) eccentrically installed on the counterbalance (9) formed on the upper end of the rotary shaft (6) in accordance with the rotation of the rotary shaft (6), the crank pin ( Rotational circular motion of 10) slides the slider 12 coupled with the crank pin 10 forward and backward (in the drawing) inside the piston shell 11, and simultaneously moves the piston 7 and the piston shell 11 to each other. The refrigerant gas is compressed by reciprocating left and right (in the drawing) inside the cylinder 8.

However, the slider 12 is coupled to the crank pin 10 eccentric in the compression mechanism as described above, and the slider 12 to move forward, backward, left, and right along with the circular motion of the crank pin 10, the piston shell (11) Since it is coupled to the crank pin 10 so as to be geometrically centered therein, the crank pin 10 is due to the rotation moment of the slider 12 according to the rotational circle motion, the slider 12 and the piston shell 11 Friction is locally performed at the upper left corner and the upper right corner of the slider 12, resulting in reduced wear and reliability of the product due to increased wear.

The friction part between the slider 12 and the piston shell 11 is the oil hole 6a of the rotating shaft 6 by the centrifugal force of the lubricating oil built in the lower part of the sealed container 1, 2 by the rotation of the rotating shaft 6. It is supplied through, but this cannot eliminate the cause of the underlying friction.

Accordingly, an object of the present invention is to provide a slider structure of a hermetic electric compressor that can improve performance as well as product life by reducing friction and abrasion generated in the process of converting the rotational motion of the rotating shaft into the reciprocating motion of the piston. .

In order to achieve the object of the present invention as described above is coupled to the piston shell and sliding formed integrally with the reciprocating piston and coupled with the crank shaft eccentrically installed on the rotating shaft to transfer the rotary movement of the rotary shaft to the linear reciprocating motion of the piston. In the hermetic electric compressor having a slider, the slider of the hermetic electric compressor, characterized in that the position of the coupling hole formed in the slider and the crank pin is coupled to be eccentrically formed in the direction of rotation of the rotary shaft from the geometric center of the slider. A structure is provided.

In addition, the distance eccentric to the rotational direction of the rotation axis from the geometric center of the slider is 0.8 Provided is a slider structure of an hermetic electric compressor.

Referring to the slider structure of the hermetic electric compressor of the present invention as described above according to the embodiment shown in the accompanying drawings as follows.

Slider structure of the hermetic electric compressor of the present invention, as shown in Figure 4, is formed of a round bar coupling hole of the crank pin 10 is coupled to the slider 12 'to the slider 12 having a predetermined length (12'a) is formed eccentrically to the right from the geometric center of the slider (12 '), that is, in the rotational direction of the above-described rotation axis.

The center of the geometry of the slider 12 'means the center of the geometry under the premise that the diameter of the round bar of the slider 12' is uniform and the density of the material is uniform.

The eccentric distance C between the center of the slider 12 'and the engagement hole 12'a is 0.8 by the experimental value. It is preferable to use.

The operational effects of the slider structure of the hermetic electric compressor of the present invention as described above are as follows.

The slider structure of the hermetic electric compressor of the present invention is inserted to slide in the piston shell 11 formed integrally with the piston 7 reciprocating in the cylinder 8, and eccentric with the geometric center of the slider 12 '. The crank pin 10 eccentrically formed with the rotating shaft 6 is coupled to the formed coupling hole 12'a, the crank pin 10 by the circular motion of the crank pin 10 due to the rotational movement of the rotating shaft 6 While reciprocating the piston 7 inside the cylinder (8) while moving in a circular motion along the piston shell (11) back and forth with the left and right movement.

In the above process, the slider structure of the present invention causes the friction moment by causing a centrifugal force due to an asymmetrical shape due to the eccentric coupling of the slider 12 'when moving inside the piston shell 11 while moving circularly by the crank pin 10. This reduces the amount of abrasion of the piston shell 11 of the slider 12 '.

FIG. 5 shows the wear state of the slider 12 'and the piston shell 11 according to the above-described geometric center of the slider 12' and the eccentric distance C of the coupling hole 12'a. ) Is to the right, i.e. 0.8 in the direction of rotation of the axis of rotation. Indicates the minimum.

Next, referring to FIG. 6, the slider 12 ′ to which the present invention is applied will be described with reference to loads and frictional forces acting on the respective parts when the slider 12 ′ moves in the piston shell as the above-described rotary shaft rotates.

In the figure, when the slider 12 'is moved to the right by the rotation of the above-described rotation shaft, the clock is between the crank pin 10 fitted in the engaging hole 12'a eccentrically by its center. Direction of rotation Mf acts. This rotation moment Mf serves to rotate the slider 12 'clockwise about its crank pin 10, and the piston shell 11 restrains its rotation. Therefore, as shown in the drawing, the slider 12 'has a small angle within a range of allowable clearance in the piston shell 11. Will tilt. As a result, the loads F ₁ and F ₂ are applied to the upper left corner 13 and the lower right corner 14 of the slider 12 ', respectively, and frictional forces f ₁ , F are proportional to the loads F ₁ , F ₂ , respectively. f ₂ acts and wear at that part proceeds. Of course, these loads F ₁ , F ₂ is a dynamic load related to the compression force F ₃ by the rotation of the rotating shaft acting in the direction of pressing the piston as the rotating shaft rotates, the largest action at the end of the compression stroke do. Since the slider 12 'is fixed relative to the piston shell 11 with respect to the compression direction thereof, the sum of the forces in the vertical direction and the sum of moments are defined as follows.

On the other hand, the frictional forces f ₁ and f ₂ issued from the upper left corner 13 and the lower right corner 14 of the slider 12 'are respectively. F ₁ , F ₂ (where Is the coefficient of friction) and F ₂ = F ₁ -F ₃ .

Likewise,

It becomes

If the eccentric distance C = 0 in equations ③ and ④,

Becomes That is, in the non-eccentric state, the load F1 acting on the upper left corner 13 of the slider is greater than the load F ₂ acting on the lower right corner 14 of the slider, so the frictional force f ₁ at the upper left corner 13 thereof. = F ₁ is large. Therefore, the wear is severe at that part and the deviation between the opposite side and the wear is severe. On the other hand, the present invention eccentrically engages the coupling hole 12'a of the slider 12 'by the eccentric distance C in the rotational direction to reduce the frictional force of the upper left corner portion 13 and reduce the deviation of the opposite side and wear. Therefore, according to the present invention, it is possible to prevent the phenomenon of aggravation of wear locally and to reduce the variation of wear as a whole, so that the effect of extending the life of the product and improving the reliability of the product is expected.

Claims (2)

In the hermetic electric compressor having a slider coupled to the piston shell formed integrally with the reciprocating piston and coupled with the crank pin eccentrically installed on the rotating shaft to transmit the rotary movement of the rotary shaft to the linear reciprocating movement of the piston, The slider structure of the hermetic electric compressor, characterized in that the position formed in the slider eccentrically coupled to the crank pin in the direction of rotation of the rotation axis from the geometric center of the slider. The distance eccentrically from the geometric center of the slider in the direction of rotation of the axis of rotation is 0.8. Slider structure of the hermetic electric compressor.